Global ETD Search

1	The biochemistry of the skipjack swimming musculature and its application to metabolic control in vertebrate white muscle Guppy, Michael January 1978 (has links) The tunas could be called the 'ultimate teleosts'. They have a high percentage of muscle and a high percentage of that muscle is red muscle, the muscles are kept at above ambient temperatures by a counter current heat exchanger and the respiratory capabilities of these fish are accordingly high. The behavioral culmination of these characteristics is manifested in swimming speeds, which can be extraordinarily high, on a sustained, or a burst basis. One of the hottest and fastest tunas, the skipjack, was used in a study to determine (1) when each muscle is active (2) when and where the muscle heat is produced and (3) what the advantage of the hot musculature is to the animal. Evidence from E. H. , histological, enzyme and metabolite studies suggest that the red muscle is qualitatively quite typical although its aerobic capacity is somewhat above that of other teleost red muscles. The white muscle has truely astounding anaerobic capabilities, but also displays an aerobic capacity not usually found in teleost white muscle. Further examination of white muscle biochemical organization revealed a GP cycle which balances redox during the aerobic catabolism of glycogen and/or glucose. Both LDH (the terminal step in anaerobic glycolysis) and GPDH (the cytoplasmic arm of the GP cycle) are present in white muscle in high activities. Since these enzymes potentially compete for a common co-substrate, NADH, a tight control of these two enzymes seemed necessary to ensure mutual exclusive activity. Metabolite regulators of both enzymes were found which by affecting the ability of each enzyme to compete for NADH, channel carbon and hydrogen to lactate and C02 and H20 under anaerobic and aerobic conditions respectively. , The effect of temperature on metabolism was investigated and it is concluded that the stability rather than the absolute 'set point' of the body temperature is the more important feature. / Science, Faculty of / Zoology, Department of / Graduate Skipjack tuna
2	Biomechanics of thunniform swimming : electromyography, kinematics, and caudal tendon function in the yellowfin tuna Thunnus albacares and the skipjack tuna Katsuwonus pelamis / Knower, Andrea Torrence, January 1998 (has links) Thesis (Ph. D.)--University of California, San Diego, 1998. / Vita. Includes bibliographical references (p. 129-130).
3	Economic aspects of the skipjack tuna industry in Hawaii Shang, Yung-Cheng, 1930 January 1969 (has links) Typescript. / Thesis (Ph. D.)--University of Hawaii, 1969. / Bibliography: leaves [136]-142. / ix, 142 l Skipjack tuna Tuna fisheries -- Hawaii
4	Economic model of a fisheries market with endogenous supply : the Hawaii skipjack tuna case Hudgins, Linda Lucas, 1946 January 1980 (has links) Photocopy of typescript. / Bibliography: leaves 107-114. / ix, 114 leaves, bound ill. 28 cm Skipjack tuna Tuna fisheries -- Hawaii Fish trade -- Hawaii
5	Analýza šifrovacích metod pro klonování disků / Analysis of Encipherement Methods for Disk Cloning Chromečka, Jiří January 2016 (has links) The presented text deals with designing of a multilingual application and its following implementation in the C++ language. The application encrypts disk volumes with Microsoft Windows system using symmetric cryptography and password authentication, where the password security strength is verified. Securing the sensitive data is one of the important security goals in area of information technology. The symmetric cryptography uses the same key for both the encryption and the decryption and due to its speed it is suitable for the data storage encryption. For the higher security it is possible to encrypt a whole disk volume with sensitive data.
6	Genetic stock structure and inferred migratory patterns of skipjack tuna (Katsuwonus pelamis) and yellowfin tuna (Thunnus albacares) in Sri Lankan waters Dammannagoda Acharige, Sudath Terrence January 2007 (has links) Tuna are the major marine fishery in Sri Lanka, and yellowfin tuna (YFT) (Thunnus albacares) and skipjack tuna (SJT) (Katsuwonus pelamis) represent 94% of all tuna caught. The tuna catch in Sri Lanka has increased rapidly over recent years and this is true generally for the Indian Ocean. Tuna are a major animal protein source for 20 million people in Sri Lanka, while marine fisheries provide the main income source for most Sri Lankan coastal communities. While the importance of the fishery will require effective stock management practices to be employed, to date no genetic studies have been undertaken to assess wild stock structure in Sri Lankan waters as a basis for developing effective stock management practices for tuna in the future. This thesis undertook such a genetic analysis of Sri Lankan T. albacares and K. pelamis stocks. Samples of both YFT and SJT were collected over four years (2001 - 2004) from seven fishing grounds around Sri Lanka, and also from the Laccadive and Maldive Islands in the western Indian Ocean. Partial mitochondrial DNA (mtDNA) ATPase 6 and 8 genes and nuclear DNA (nDNA) microsatellite variation were examined for relatively large samples of each species to document genetic diversity within and among sampled sites and hence to infer stock structure and dispersal behaviour. Data for YFT showed significant genetic differentiation for mtDNA only among specific sites and hence provided some evidence for spatial genetic structure. Spatial Analysis of Molecular Variance (SAMOVA) analysis suggests that three geographically meaningful YFT groups are present. Specifically, one group comprising a single site on the Sri Lankan west coast, a second group comprising a single site on the east coast and a third group of remaining sites around Sri Lanka and the Maldive Islands. Patterns of variation at nDNA loci in contrast, indicate extensive contemporary gene flow among all sites and reflect very large population sizes. For SJT, both mtDNA and nDNA data showed high levels of genetic differentiation among all sampling sites and hence evidence for extensive spatial genetic heterogeneity. MtDNA data also indicated temporal variation within sites, among years. As for YFT, three distinct SJT groups were identified with SAMOVA; The Maldive Islands in the western Indian Ocean comprising one site, a second group comprising a single site on the east coast and a third group of remaining sites around Sri Lanka and the Laccadive Islands. The mtDNA data analyses indicated two divergent (M^ = 1.85% ) SJT clades were present among the samples at all sample sites. SJT nDNA results support the inference that multiple 'sub populations' co-exist at all sample sites, albeit in different frequencies. It appears that variation in the relative frequencies of each clade per site accounts for much of the observed genetic differentiation among sites while effective populations remain extremely large. Based on combined data sets for management purposes therefore, there is no strong evidence in these data to indicate that more than a single YFT stock is present in Sri Lankan waters. For SJT however, evidence exists for two divergent clades that are admixed but not apparently interbreeding around Sri Lanka. The identity of spawning grounds of these two clades is currently unknown but is likely to be geographically distant from Sri Lanka. Spawning grounds of the two distinct SJT clades should be identified and conserved. tuna skipjack tuna yellowfin tuna population genetics population structure migration fisheries management Sri Lanka Maldives Indian Ocean demography
7	Age and Growth of Three Coastal Pelagic Tuna Species in the Florida Straits Adams, Jessica L. 01 March 2013 (has links) Understanding the life history of a species is essential for fully understanding its role within an ecosystem. However, many of the fish species of high ecological value have not been studied due to their less prominent roles in local recreational and commercial fisheries in comparison to other targeted species. This study describes the age and growth patterns of three small tuna species inhabiting South Florida waters: blackfin tuna Thunnus atlanticus, little tunny Euthynnus alletteratus, and skipjack tuna Katsuwonus pelamis. Tuna specimens were collected via donations obtained from various fishing tournaments and charter captains in the areas of the Florida Straits as well as hook-and-line by the Nova Southeastern University Oceanographic Center. Age was described via sagittal otolith deposition patterns. They were removed, dried, sectioned, and rings were counted as well as measured. Validation of the timing of ring deposits was done by marginal increment analysis. Growth parameters were determined by comparison of fish fork length to count measurements. This comparison via the Von Bertalanffy growth equation produced a growth rate for each species: blackfin, L∞ = 95.34 cm, K = 0.28, and t0 = -1.53; little tunny, L∞ = 77.93 cm, K = 0.69, and t0 = -0.69; and skipjack, L∞ = 112.76 cm, K = 0.24, and t0 = -1.70. The curves indicate an average size of an individual of a given species at a certain age. They also give an estimation of a maximum length (L∞) of each species, in addition to specific growth rate, which is indicated by the slope. Parameters of each resulting Von Bertalanffy equation were compared among species. Results were also compared with growth rates currently used in stock assessments by fisheries management organizations, such as the International Commission for the Conservation of Atlantic Tunas (ICCAT). Blackfin tuna Thunnus atlanticus Little tunny Euthynnus alletteratus Skipjack tuna Katsuwonus pelamis Age and growth Otoliths Atlantic Marine Biology
8	Šifrování telefonních hovorů / Encrypting Landlines Phone Communication Vávra, Jakub January 2008 (has links) This master's thesis is about making draft and implementing land-line phone call encryption using FITkit. The ultimate goal is to find suitable compression and encryption methods, implement or adapt them for FITkit board and create functional solution.
9	Développement d'une méthode méthodologie de PCR en temps réel pour l'identification et la quantification de trois espèces de thon (Thunnus obesus, Thunnus albacares et Katsuwonus pelamis) dans les produits appertisés / Development of a methodology of PCR in real time for identification and quantification of 3 species of tuna (Thunnus obesus, Thunnus albacares and Katsuwonus pelamis) in canned products Bojolly, Daline 29 March 2017 (has links) Le thon obèse (Thunnus obesus), le thon alabore (Thunnus albacares) et le listao (Katsuwonus pelamis) comptent parmi les espèces de thons les plus utilisées en conserve. Lors de la fabrication de conserves de thon, la substitution d'espèce et/ou le mélange de différentes espèces de thon sont interdits par la réglementation européenne. L'authentification des espèces de thon reste complexe à cause du degré de similitude élevé entre les espèces de thon, ou encore, lorsque les caractéristiques morphologiques externes sont éliminées au cours du filetage et lors de la mise en conserve. Par conséquent, des substitutions involontaires ou frauduleuses peuvent se produire. Dans cette étude, le marqueur mitochondrial du gène de la sous-unité 2 de la NADH déshydrogénase a été utilisé pour identifier le thon obèse et le gène de la sous-unité II de la cytochrome c oxydase a été utilisé pour identifier le thon albacore et le listao en utilisant la PCR en temps réel basée sur la technologie TaqMan. Deux méthodes différentes basées sur la qPCR ont été développées pour quantifier le pourcentage de chair de chaque espèce présente au sein d'une boîte de thon. La première a été basée sur la quantification absolue avec standard externe réalisée avec les deux marqueurs. La seconde a été basée sur la quantification relative avec standard externe avec le gène endogène de l'ARN 12S. Sur la base de ces résultats, nous pouvons conclure que notre méthode peut s'appliquer pour quantifier les deux espèces de thon albacore et obèse génétiquement très proches lorsqu'elles sont utilisées dans un mélange binaire en conserve. / Bigeye tuna (Thunnus obesus), yellowfin tuna (Thunnus albacares) and skipjack tuna (Katsuwonus pelanis) are among the most widely used tuna species for canning purposes. Not only substitution but also mixing of tuna species is prohibited by the European regulation for canned tuna products. However, it can be difficult to authenticate the tuna species, due to their high degree of similarity or even when the external morphological characteristics are removed due to filleting before canning. Consequently, involuntary or fraudulent substitutions may occur during the canning process. In this study, the mitochondrial marker from NADH dehydrogenase subunit 2 gene was used to identify bigeye tuna and the mitochondrial marker cytochrome c oxidase subunit II gene was used to identify yellowfin tuna and skipjack tuna, utilizing TaqMan qPCR methodology. Two different qPCR-based methods were developed to quantify the percentage of flesh of each species used for can processing. The first one was based on absolute quantification using standard curves realized with these two markers ; the second one was founded on relative quantification with the universal 12S rRNA gene as the endogenous gene. On the basis of our results, we conclude that our methodology could be applied to authenticate the two closely related tuna species (bigeye tuna and yellowfin tuna) when used in a binary mix in tuna cans. Thon Identification Quantification Appertisation TaqMan QPCR Thon obèse (Thunnus obesus) Thon albacore (Thunnus albacares) Listao (Katsuwonus pelamis) Tuna Authentication Quantification Canned products TaqMan QPCR Bigeye Tuna (Thunnus obesus) Yellowfin tuna (Thunnus albacares) Skipjack tuna (Katsuwonus pelamis)
10	Tsunamigenic potential of crustal faults in the southern Strait of Georgia and Boundary Bay Caston, Megan 31 August 2021 (has links) In this thesis, I constrain rupture scenarios of active crustal faults in the southern Strait of Georgia and Boundary Bay in order to assess their tsunamigenic potential. The NW-SE-trending Drayton Harbor, Birch Bay, and Sandy Point faults had been previously identified on the southern side of Boundary Bay from aeromagnetic, LiDAR, and paleoseismic data; all show evidence of abrupt vertical Holocene displacements. South of Boundary Bay, the E-W-trending Skipjack Island fault zone was recently mapped on the basis of multibeam sonar imagery and seismic reflection data, with evidence for Holocene offsets of the seafloor and subsurface sediments. In addition, the Fraser River Delta fault had been hypothesized on the basis of a line of pockmarks and fluid seeps. Since these faults have only been recently mapped and identified as active, there is little information available on their structure, rupture style, and past large earthquakes. This makes it difficult to constrain rupture models to predict how fault slip could displace the seafloor during a large earthquake, for input to tsunami models. I analyzed relocated earthquake hypocentres, earthquake mechanisms, bathymetry, topography, and aeromagnetic, seismic reflection, and magnetotelluric data, to constrain the location, strike, dip, and rupture width of each fault. Correlations between datasets enabled mapping of northwestward extensions of the Sandy Point and Birch Bay faults, as well as delineating the previously unmapped Fraser River Delta fault. These offshore faults appear to be associated with infilled basement valleys in the subsurface, perhaps due to differential glacial erosion of weakened fault zone material. The Drayton Harbor fault could not be definitively mapped across Boundary Bay, so was excluded from the rupture modelling. Rupture styles were constrained using a combination of earthquake mechanisms, stress orientations, other evidence of regional compression, and vertical paleoseismic offsets. Where possible, paleoseismic displacements in past earthquakes were used to constrain the amount of fault slip for scenario earthquakes; empirical relations between fault slip and fault length or area were used to estimate displacements for the Skipjack Island and Fraser River Delta faults. The Birch Bay, Sandy Point, Skipjack Island, and Fraser River Delta faults all pose a significant tsunami risk to communities surrounding the southern Strait of Georgia and Boundary Bay. Considering both the originally mapped and extended lengths, the Birch Bay and Sandy Point faults could rupture in reverse-faulting earthquakes up to Mw 6.7-7.4 and 6.8-7.5, respectively, with seafloor uplift up to 2-2.5 m triggering damaging tsunami waves (up to at least 2.5 m) that could arrive onshore with little to no warning after the shaking begins. Similarly, the Fraser River Delta fault could host reverse or dextral-reverse slip earthquakes up to Mw 7.0-7.6, with seafloor uplift of 0.6-3.5 m. Ruptures on the Skipjack Island fault would likely have a larger strike-slip component; earthquakes of Mw 6.9-7.3 produce modelled seafloor uplift of 0.5-1.9 m. These results suggest that large tsunamigenic earthquakes on crustal faults in the southern Strait of Georgia should be included in future seismic and tsunami hazard assessments on both sides of the international border. / Graduate Tsunami Hazard Boundary Bay Fraser River Delta Fault Sandy Point Fault Skipjack Island Fault Birch Bay Fault Drayton Harbor Fault Strait of Georgia Fault mapping and constraints Rupture Models Seismic Reflection Aeromagnetic Fault locating using Geophysical methods Earthquake Mechanisms

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